CN103170734A - Laser processing device and laser processing method - Google Patents

Abstract

An embodiment of the invention refers to a laser processing device (1) possessing a light source (20), a plurality of intensity conversion lenses (11) used for converting laser intensity distribution from light sources, reforming the intensity distribution into desired intensity distribution and respectively generating different wave surfaces, a condensing lens (50) used for condensing laser from the intensity conversion lenses on processing positions in a processed object (100) and a control part (80) used for switching the plurality of intensity conversion lenses (11)under the condition of changing processing positions.

Description

Laser processing device and laser processing

Technical field

The present invention relates to carry out laser processing device and the laser processing of the processing of workpiece inside.

Background technology

Generally speaking, most to have as Gaussian distribution near central authorities be intensity distribution the strongest and that gradually die down towards periphery to laser.Yet, in Laser Processing etc., wish to have spatially intensity distribution uniformly.About this point, in patent documentation 1, disclose use homogenizer (homogenizer) and made the intensity distribution of laser even.The disclosed laser processing device of this patent documentation 1 is the inside of wafer (wafer) to be processed the device of (upgrading), and is the wire that tilts with thickness direction with laser focusing in order to shorten the process time in the wafer of processing scantling.

Patent documentation

Patent documentation 1: Japanese Patent Application Publication 2009-172633 communique

Summary of the invention

Yet, in the situation that with laser focusing in workpiece inside, can produce aberration (wave surface distortion (wave front distortion)), and the optically focused area extension.In the disclosed laser processing device of patent documentation 1, because there is no to consider the aberration that produces in workpiece inside, so cutter trade can be expanded on the working depth direction, have and produce the unexpected worry of isolating.In addition, in the situation that until form cutter trade near the back side, have the worry that penetrates into the back side.

Have, the aberration that produces in workpiece inside is according to the position of the depth direction of workpiece inside and difference again.

Therefore, even the object of the present invention is to provide a kind of in the situation that the different position of the depth direction of workpiece inside is processed laser processing device and the laser processing that also can carry out rightly the aberration correction.

The present application people have carried out concentrated research, found that, change by utilizing the wave surface that is produced by the uniform intensity-conversion lens of intensity distribution that are used for making laser, thereby can revise the aberration that produces in workpiece inside.In addition, the present application people have carried out concentrated research, found that, changed by making phase place correction lens in the homogenizer (homogenizer) that is consisted of by intensity-conversion lens and phase place correction lens have wave surface, thereby can revise the aberration that produces in workpiece inside.

Therefore, laser processing device of the present invention is with the laser processing device of laser focusing in the workpiece inside with photopermeability, possesses: the light source that (a) generates laser; (b) conversion come from light source laser intensity distribution and be shaped as the polishing shaped part of desirable intensity distribution; The collector lens of the Working position of the laser focusing that (c) will come from the polishing shaped part in workpiece inside; (d) control the control part of polishing shaped part.And the polishing shaped part has: (b1) change the intensity distribution of the laser that comes from light source and be shaped as desirable intensity distribution, and generating respectively a plurality of intensity-conversion lens of different wave surfaces; Perhaps (b2) conversion come from light source laser intensity distribution and be shaped as the phase place of the intensity-conversion lens of desirable intensity distribution and the shoot laser that correction comes from the intensity-conversion lens and generate respectively a plurality of phase place correction lens of different wave surfaces, control part, (d1) in the situation that the change Working position switches a plurality of intensity-conversion lens or a plurality of phase place correction lens.

In addition, laser processing of the present invention is the laser processing of laser processing device, and described laser processing device possesses: the light source that (a) generates laser; (b) conversion come from light source laser intensity distribution and be shaped as the polishing shaped part of desirable intensity distribution; The collector lens of the Working position of the laser focusing that (c) will come from the polishing shaped part in workpiece inside.At this, the polishing shaped part has: (b1) change the intensity distribution of the laser that comes from light source and be shaped as desirable intensity distribution, and generating respectively a plurality of intensity-conversion lens of different wave surfaces; Perhaps (b2) conversion come from light source laser intensity distribution and be shaped as the phase place of the intensity-conversion lens of desirable intensity distribution and the shoot laser that correction comes from these intensity-conversion lens and generate respectively a plurality of phase place correction lens of different wave surfaces.This laser processing, (e1) set or change workpiece inside in Working position, (e2) corresponding to setting or the change of Working position, switch a plurality of intensity-conversion lens or a plurality of phase place correction lens, (e3) will come from the Working position of Ear Mucosa Treated by He Ne Laser Irradiation in workpiece of light source.

According to this laser processing device and laser processing, for example in the situation that the polishing shaped part has a plurality of intensity-conversion lens, because a plurality of intensity-conversion lens generate respectively different correction wave surfaces, control part switches a plurality of intensity-conversion lens corresponding to the change of Working position, so, even change Working position (working depth) also can carry out appropriate aberration correction.In addition, for example in the situation that the polishing shaped part has intensity-conversion lens and a plurality of phase place correction lens, because a plurality of phase place correction lens generate respectively different correction wave surfaces, control part switches a plurality of phase place correction lens corresponding to the change of Working position, so, even change Working position (working depth) also can carry out appropriate aberration correction.

A plurality of intensity-conversion lens in preferred above-mentioned laser processing device or a plurality of phase place correction lens generate respectively for the aberration of revising laser and correspond respectively to different of a plurality of correction wave surfaces of a plurality of Working positions of workpiece inside.In the case, in above-mentioned laser processing device, preferred control part (d1) in the situation that a plurality of Working positions of change, is selected to generate corresponding to the lens of the correction wave surface of the Working position that changes and switches from a plurality of intensity-conversion lens or a plurality of phase place correction lens.On the other hand, in above-mentioned laser processing, preferably (e2) corresponding to setting or the change of a plurality of Working positions, selects generation corresponding to the lens of the correction wave surface of the Working position that sets or change and switches from a plurality of intensity-conversion lens or a plurality of phase place correction lens.

According to the present invention, even in the situation that the different position of the depth direction of workpiece inside is processed, also can carry out rightly the aberration correction.

Description of drawings

Fig. 1 means the pie graph of an example of homogenizer (homogenizer).

Fig. 2 means the figure of an example of the desirable intensity distribution of example of intensity distribution of the incident laser in homogenizer and shoot laser.

Fig. 3 means the schematic diagram of an example of the shape of intensity-conversion lens.

Fig. 4 means the schematic diagram of an example of the shape of phase place correction lens.

Fig. 5 means to the schematic diagram of the measurement result of an example of the spatial model of the incident laser of intensity-conversion lens (intensity distribution).

Fig. 6 means that the shoot laser that comes from the intensity-conversion lens propagated the schematic diagram of measurement result of an example of the spatial model (intensity distribution) after 685mm.

Fig. 7 means the schematic diagram of an example of mensuration system.

Fig. 8 means the schematic diagram of measuring in the result of an example of the locational wave surface of carrying collector lens in Fig. 7 represented mensuration system.

Fig. 9 means for revising in the situation that make the schematic diagram of an example of the correction wave surface of the spherical aberration that the Working position (degree of depth) of laser focusing in workpiece inside produce.

Figure 10 means the schematic diagram of variation of the shape of phase place correction lens.

Figure 11 means the schematic diagram of the wave surface that is produced by the represented phase place correction lens of Figure 10.

Figure 12 means the pie graph of the laser processing device that the 1st embodiment of the present invention is related.

Figure 13 means the flow chart of the step of the laser processing that the 1st embodiment of the present invention is related.

Figure 14 means the schematic diagram of result of the focal point of in Fig. 7 represented mensuration system observation collector lens under the state of working strength convertible lens not.

Figure 15 means that in Fig. 7 represented mensuration system observation used the schematic diagram of result of the focal point of the collector lens under the state of intensity-conversion lens.

Figure 16 means the focal point schematic diagram of the result of the line figure (beam profile) at 10 μ m places to the front more of measuring the ratio collector lens under the state of working strength convertible lens not in Fig. 7 represented mensuration system.

Figure 17 means the focal point schematic diagram of the result of the line figure at 10 μ m places to the front more of measuring the ratio collector lens under the state that has used the intensity-conversion lens in Fig. 7 represented mensuration system.

Figure 18 means the pie graph of the laser processing device that the 2nd embodiment of the present invention is related.

Figure 19 means the flow chart of the step of the laser processing that the 2nd embodiment of the present invention is related.

Figure 20 means the pie graph of the laser processing device that the 3rd embodiment of the present invention is related.

Figure 21 means the pie graph of the laser processing device that the 4th embodiment of the present invention is related.

Figure 22 means the pie graph of the laser processing device that the 5th embodiment of the present invention is related.

Figure 23 means the pie graph of the laser processing device that the variation of the 1st embodiment is related.

Figure 24 means the pie graph of the laser processing device that the variation of the 2nd embodiment is related.

Figure 25 means the pie graph of the laser processing device that the variation of the 3rd embodiment is related.

The specific embodiment

Below, with reference to accompanying drawing, preferred embodiment be described in detail of the present invention.Also have, in each accompanying drawing, for the identical or suitable identical symbol of part mark.

Before the explanation embodiments of the present invention, a method of the aspheric shape design of homogenizer (homogenizer) and homogenizer is described.Fig. 1 means the pie graph of an example of homogenizer.This homogenizer 10X is shaped to the homogenizer of shape arbitrarily for the intensity distribution with laser, possesses a pair of non-spherical lens 11X, 12X.The non-spherical lens 11X of light incident side is shaped to arbitrarily the intensity-conversion lens of shape as the intensity distribution with laser and brings into play function, the non-spherical lens 12X of exiting side as make shaping the consistent and phase place correction lens that be modified to plane wave of the phase place of laser bring into play function.In this homogenizer 10X, can pass through a pair of non-spherical lens 11X, the aspheric shape design of 12X generates the shoot laser Oo that the intensity distribution of incident laser Oi is shaped to desirable intensity distribution.

Below, a pair of non-spherical lens 11X in illustration homogenizer 10X, an example of the aspheric shape design of 12X.For example, desirable intensity distribution is set in laser processing device etc. on desirable space uniformly intensity distribution, be uniform strength distribute (Oo of Fig. 2).At this, desirable intensity distribution is necessary to set with the mode that the energy (area of intensity distribution) of incident laser Oi equates with the energy of shoot laser Oo (area of desirable intensity distribution).Therefore, for example the setting of uniform strength distribution can be carried out as described below.

The intensity distribution of incident laser Oi is illustrated in figure 2 as the Gaussian distribution (wavelength 532nm) of concentric circles.Gaussian distribution is because of represented by following (1) formula, so the radius r of incident laser Oi ₁Scope in energy become following (2) formula.

[several 1]

$I_1\left(r\right)=\exp \{-{\left(\frac{r}{\mathrm{\ω}}\right)}^2\}\·\·\·\left(1\right)$

[several 2]

$\underset{-r_1}{\overset{r_1}{\∫}}{I}_1\left(r\right)\mathrm{dr}\·\·\·\left(2\right)$

In the case, because Gaussian distribution becomes Rotational Symmetry with radius 0mm as the center, so resolve to design aspherical shape according to one dimension.

On the other hand, the desirable intensity distribution of shoot laser Oo is set uniform strength distribution (times N) as shown in Figure 2 for.Uniform strength distributes because represented by following (3) formula, thus as shown in following (4) formula with the radius r of shoot laser Oo ₂Scope in the mode that equates with the energy of incident laser Oi of energy set the value E of the even intensity section of shoot laser Oo _o

[several 3]

$I_2\left(r\right)={\mathrm{<figure-callout\; id="0"\; label="E"\; filenames="HDA00002658488800021.png,HDA00002658488800031.png"\; state="\{\{state\}\}">E</figure-callout>}}_0\&times;\exp \{-{\left(\frac{r}{\mathrm{\&omega;}}\right)}^{2N}\}\&CenterDot;\&CenterDot;\&CenterDot;\left(3\right)$

[several 4]

$\underset{-r_1}{\overset{r_1}{\&Integral;}}{I}_1\left(r\right)\mathrm{dr}=\underset{-r_2}{\overset{r_2}{\&Integral;}}{I}_2\left(r\right)\mathrm{dr}\&CenterDot;\&CenterDot;\&CenterDot;\left(4\right)$

Also have, if according to this method, the desirable intensity distribution of the shoot laser after shaping also can only not become the function of regulation, can be intensity distribution arbitrarily.

Afterwards, as shown in Figure 1, has the mode of the shoot laser Oo of desirable intensity distribution with the intensity distribution that becomes the incident laser Oi in intensity-conversion lens 11X in phase place correction lens 12X, the light of weak intensity that namely is diffused into periphery and periphery with near the high-intensity light the central authorities in incident laser Oi is by the mode of optically focused, tries to achieve as the light path P1 on from the aspheric surface 11a of intensity-conversion lens 11X to the coordinate arbitrarily of the radial direction of the non-spherical lens of the light path of the aspheric surface 12a of phase place correction lens 12X ~ P8.

Afterwards, based on the light path P1 that tries to achieve ~ P8, ask for the shape of the aspheric surface 11a of intensity-conversion lens 11X.Particularly, to obtain the mode of light path P1 ~ P8, radius r is asked for as benchmark in the center of intensity-conversion lens 11X ₁The difference of height of aspheric surface 11a on each coordinate of direction.So, as shown in Figure 3, try to achieve the shape of the aspheric surface 11a of intensity-conversion lens 11X.

On the other hand, the shape of the aspheric surface 12a of the phase place correction lens 12X mode that becomes plane wave so that the phase place of the laser in light path P1 ~ P8 is consistent is asked for.Particularly, radius r is asked for as benchmark in the center of phase place correction lens 12X ₂The difference of height of aspheric surface 12a on each coordinate of direction.So, as shown in Figure 4, try to achieve the shape of the aspheric surface 12a of phase place correction lens 12X.

Also have, Fig. 3 and Fig. 4 are as non-spherical lens 11X, the material of 12X and use MgF ₂(n=1.38), with center (the coordinate r of aspheric surface 11a ₁=0 position) with center (the coordinate r of aspheric surface 12a ₂An example when interval=0 position) is designed to L=685mm.

At this, by imaging lens system and measured the spatial model (intensity distribution) of incident laser of the intensity-conversion lens 11X in the homogenizer 10X by line figure instrument (beam profiler) and the 685mm that comes from the shoot laser of the intensity-conversion lens 11X spatial model (intensity distribution) after propagating.These measurement results are shown in Fig. 5 and Fig. 6.Thus, according to intensity-conversion lens 11X, after the L=685mm as lens intervals design load propagated, can confirm can be basically as design, the intensity distribution of laser is shaped as uniform intensity distribution on the space.

Then, the wave surface distortion (wave front distortion) that is produced by the intensity-conversion lens 11X in homogenizer 10X with the represented mensuration systematic survey of Fig. 7.In this mensuration system, the laser that will come from LASER Light Source 20 by amplifier (expander) 30 enlarges and incides intensity-conversion lens 11X.The shoot laser that comes from intensity-conversion lens 11X incides collector lens 50 by speculum 21,22 and imaging optical system 40.In amplifier 30, use the set of lenses that is consisted of by a pair of concavees lens 31 and convex lens 32, and enlarge and come from the laser of LASER Light Source 20, thereby make beam diameter be suitable for the diameter of intensity-conversion lens 11X.In addition, in imaging optical system 40, use the set of lenses that is consisted of by a pair of lens 41,42, make the pupil face that images in collector lens 50 in the locational wave surface that disposes phase place correction lens, and make beam diameter be suitable for the PD of collector lens 50.This be due to, in the situation that do not dispose phase place correction lens, in addition, even in the situation that with phase place correction lens configuration in the design attitude of intensity-conversion lens, in fact, avoided making intensity distribution or wave surface occur crooked corresponding to propagation distance.

In this mensuration system, measured by wavefront sensor and be equipped with the locational wave surface of collector lens 50.This measurement result is shown in Fig. 8.According to Fig. 8, the intensity-conversion lens of intensity-conversion lens 11X for the intensity distribution of incident laser is carried out shaping still, also change the wave surface (in other words, the phase place of incident laser) of incident laser simultaneously.

On the other hand, in Fig. 9 representation case as in order to revise in the situation that the laser focusing that uses the collector lens of NA=0.8, focal length f=1.8mm and make wavelength 532nm in SiC(refractive index 2.6) the correction wave surface correction wave surface of the spherical aberration that produces of the position of the inner degree of depth 94 μ m and needs, before collector lens incident.

According to Fig. 8 and Fig. 9, both wave surfaces are similar.Like this, the present application it is found that by utilizing the wave surface that is produced by intensity-conversion lens 11X to change, thereby can revise the aberration that produces in workpiece inside.

In addition, the present application it is found that, by constant intensity convertible lens 11X and utilize the wave surface that is produced by the phase place correction lens 12X that is used for making phase place by the laser after intensity-conversion lens 11X shaping unanimously to be modified to plane wave to change, thereby can revise the aberration that produces in workpiece inside.For example, as shown in figure 10, if make the shape distortion of phase controlling lens, obtain the represented wave surface of Figure 11.This wave surface is equivalent to for revising in SiC(refractive index 2.6) the correction wave surface of the spherical aberration that produces on the position of the inner degree of depth 200 μ m.

[the 1st embodiment]

Figure 12 means the pie graph of the laser processing device that the 1st embodiment of the present invention is related.The laser processing device 1 of the 1st embodiment possesses LASER Light Source 20, amplifier 30, a plurality of intensity-conversion lens 11, lens mount 15, collector lens 50, driver element 51, platform 52, surface observation unit 60, dichronic mirror (dichroic mirror) 61, focus unit 70, dichronic mirror 71 and control part 80 automatically.Also have, in the 1st embodiment, a plurality of intensity-conversion lens 11 are equivalent to the polishing shaped part that claim is put down in writing.

LASER Light Source 20 for example generate wavelength 532nm Gaussian-shaped laser and to amplifier 30 output.Amplifier 30 for example is made of a pair of concavees lens 31 and convex lens 32, enlarges the laser come from LASER Light Source 20 and any one output in a plurality of intensity-conversion lens 11.

A plurality of intensity-conversion lens 11 generate respectively different correction wave surfaces, this correction wave surface in order to revise in the situation that the correction wave surface that the spherical aberration that laser focusing is produced in workpiece inside needs.Corresponded respectively to a plurality of different Working position (degree of depth) of workpiece inside by the correction wave surface of a plurality of intensity-conversion lens 11 generations.A plurality of intensity-conversion lens 11 are equipped on lens mount 15.

Lens mount 15 becomes discoid, is arranged with a plurality of intensity-conversion lens 11 at its periphery.Lens mount 15 makes a plurality of intensity-conversion lens 11 optionally corresponding to laser by rotation.

The laser focusing that collector lens 50 will come from intensity-conversion lens 11 is in the Working position (degree of depth) of the regulation that is disposed at workpiece 100 inside on platform 52.Collector lens 50 can be movable by driver element 51.In addition, workpiece 100 also can be movable by platform 52.Movably being controlled by control part 80 of driver element 51 and platform 52.

In the present embodiment, between intensity-conversion lens 11 and collector lens 50, dispose successively the dichronic mirror 61,71 for surface observation unit 60 and the unit 70 of automatically focusing.The surface of workpiece is observed in surface observation unit 60 by dichronic mirror 61.In addition, the unit 70 of automatically focusing detects until the distance till the surface of workpiece by dichronic mirror 71.

The output of the laser in control part 80 control LASER Light Sources 20/output stops.In addition, control part 80 is in the situation that switch the Working position of workpiece 100 inside, make in driver element 51 and platform 52 one is movable at least arbitrarily, and the one at least arbitrarily in mobile collector lens 50 and workpiece 100.For example, control part 80 uses focusing unit 70 automatically, and by the relative position of control collector lens 50 with workpiece 100, thereby switch the Working position of workpiece 100 inside.

In addition, control part 80 makes lens mount 15 rotations, and switches to the intensity-conversion lens 11 of the aberration that can revise on this Working position in the situation that switch the Working position of workpiece 100 inside.For example, control part 80 storage can be revised a plurality of Working positions and generation at a plurality of intensity-conversion lens 11 of the correction wave surface of the aberration that produces respectively on a plurality of Working positions and set up in advance information after related.Then, control part 80 is based on this information, selects corresponding to the intensity-conversion lens 11 of the Working position that switches from a plurality of intensity-conversion lens and switches.

Figure 13 means the flow chart of the step of the laser processing that the 1st embodiment of the present invention is related.At first, focal point is set in the surface of workpiece 100, and with this position as working origin (step S01).Then, the Working position (degree of depth) (step S02) in setting workpiece 100 inside.

Then, selection can be revised the intensity-conversion lens of the spherical aberration on the Working position of having set and switch (step S03).Then, in the mode of laser focusing in the Working position of having set, platform 52 is moved.Then, irradiation laser begins processing.So laser focusing is in the Working position (step S04) of setting.

Then, when process finishing, stop Ear Mucosa Treated by He Ne Laser Irradiation (step S05).In the situation that there is in addition Working position, turn back to step S02, in the situation that do not have, finish the processing (step S06) of this workpiece 100.

Also have, for with laser focusing in the Working position of having set (degree of depth), the relative position of collector lens and workpiece is changed, so, also can replace the movement of the workpiece 100 that is undertaken by platform 52 and by driver element 51, collector lens 50 be moved, both are moved.Also have, in the situation that collector lens 50 is moved, when the entrance pupil of collector lens 50 and intensity-conversion lens 11 are in imaging relations, be necessary to move with the unit of the light-gathering optics till 50 from intensity-conversion lens 11 to collector lens.

As previously discussed, laser processing device 1 and laser processing according to the 1st embodiment, because possess a plurality of intensity-conversion lens 11 that generate respectively different correction wave surfaces, control part 80 switches a plurality of intensity-conversion lens 11 corresponding to the change of Working position, even so change Working position (working depth) also can carry out appropriate aberration correction.In other words, according to laser processing device 1 and the laser processing of the 1st embodiment, the aberration correction on Working position (degree of depth) arbitrarily becomes possibility.

Yet, also considered to replace and possessed a plurality of intensity-conversion lens and usage space optical modulator (below, be called SLM) as the 1st embodiment, and changed the method for the correction wave surface in SLM.But, in the situation that use SLM, be envisioned that expansion of laser light and only the central part of laser cut out use, be envisioned that the utilization ratio variation of laser.On the other hand, according to the 1st embodiment, because make the intensity-conversion lens self hold the aberration debugging functions, thus can utilize the laser of the pupil region that incides collector lens fully, and can improve the utilization ratio of laser.

In addition, according to laser processing device 1 and the laser processing of the 1st embodiment, by intensity-conversion lens 11, can not destroy the surface of workpiece, and can only process expeditiously inside.Below represent its result.

Figure 14 means the schematic diagram of result of the focal point of in Fig. 7 represented mensuration system observation collector lens 50 under the state of working strength convertible lens 11X not, and Figure 15 means that in Fig. 7 represented mensuration system observation used the schematic diagram of result of the focal point of the collector lens 50 under the state of intensity-conversion lens 11X.According to Figure 14 and Figure 15, by working strength convertible lens 11X, thereby increased the effective NA of collector lens 50, luminous point (spot) diameter diminishes.Thus, can be expeditiously the Working position of workpiece inside be processed.

On the other hand, Figure 16 means the schematic diagram of focal point result of the line figure at (collector lens side) 10 μ m places more to the front of measuring the ratio collector lens 50 under the state of working strength convertible lens 11X not in Fig. 7 represented mensuration system, and Figure 17 means the more schematic diagram of the result of the line figure at 10 μ m places to the front of focal point that in Fig. 7 represented mensuration system measurement used the ratio collector lens 50 under the state of intensity-conversion lens 11X.According to Figure 16 and Figure 17, by working strength convertible lens 11X, thereby increased than the focal point of collector lens 50 more to the front beam area at 10 μ m places, reduced the luminous intensity of per unit area.The damaged surfaces of having avoided thus, workpiece.

[the 2nd embodiment]

Figure 18 means the pie graph of the laser processing device that the 2nd embodiment of the present invention is related.The laser processing device 2 of the 2nd embodiment replaces a plurality of intensity-conversion lens 11 and possesses 1 intensity-conversion lens 11, then having in laser processing device 1, and is different from the 1st embodiment on the formation that possesses a plurality of phase place correction lens 12.In addition, the laser processing device 2 of the 2nd embodiment possesses on the formation of control part 80A different from the 1st embodiment replacing control part 80.Other formation of laser processing device 2 is identical with laser processing device 1.Also have, in the 2nd embodiment, intensity-conversion lens 11 and a plurality of phase place correction lens 12 are equivalent to the polishing shaped part that claim is put down in writing.

A plurality of phase place correction lens 12 generate respectively different correction wave surfaces, this correction wave surface in order to revise in the situation that the correction wave surface that the spherical aberration that laser focusing is produced in workpiece inside needs.The correction wave surface of a plurality of phase place correction lens 12 corresponds respectively to a plurality of different Working position (degree of depth) of workpiece inside.A plurality of phase place correction lens 12 are equipped on lens mount 15.

Lens mount 15 becomes discoid, is arranged with a plurality of phase place correction lens 12 at its periphery.Lens mount 15 makes a plurality of phase transition lens 12 optionally corresponding to laser by rotation.

Control part 80A is identical with control part 80, and the output of the laser in control LASER Light Source 20/output stops.In addition, control part 80A is identical with control part 80, in the situation that switch the Working position of workpiece 100 inside, make any at least one in driver element 51 and platform 52 movable, and the one at least arbitrarily in mobile collector lens 50 and workpiece 100.

In addition, control part 80A makes lens mount 15 rotations, and switches to the phase place correction lens 12 of the aberration that can revise on this Working position in the situation that switch the Working position of workpiece 100 inside.For example, control part 80A storage can be revised a plurality of Working positions and generation at a plurality of phase place correction lens 12 of the correction wave surface of the aberration that produces respectively on a plurality of Working positions and set up in advance information after related.Then, control part 80A is based on this information, selects corresponding to the phase place correction lens 12 of the Working position that switches from a plurality of phase place correction lens and switches.

Figure 19 means the flow chart of the step of the laser processing that the 2nd embodiment of the present invention is related.At first, identical with the 1st embodiment, focal point is set in the surface of workpiece 100, and with this position as working origin (step S01).Then, the Working position (degree of depth) (step S02) in setting workpiece 100 inside.

Then, in the 2nd embodiment, selection can be revised the phase place correction lens of the spherical aberration on the Working position (degree of depth) of having set and switch (step S13).Then, identical with the 1st embodiment, in the mode of laser focusing in the Working position of having set (degree of depth), platform 52 is moved.Then, irradiation laser begins processing.So laser focusing is in the Working position (step S04) of having set.

Then, when process finishing, stop Ear Mucosa Treated by He Ne Laser Irradiation (step S05).In the situation that there is in addition Working position, turn back to step S02, in the situation that do not have, finish the processing (step S06) of this workpiece 100.

As previously discussed, laser processing device 2 and laser processing according to the 2nd embodiment, because possess a plurality of phase place correction lens 12 that generate respectively different correction wave surfaces, control part 80A switches a plurality of phase place correction lens 12 corresponding to the change of Working position, even so change Working position (working depth) also can carry out appropriate aberration correction.In other words, even laser processing device 2 and the laser processing of the 2nd embodiment also can carry out the aberration correction on Working position (degree of depth) arbitrarily.

In addition, even in the 2nd embodiment, because make phase place correction lens self hold the aberration debugging functions, thus also can utilize the laser of the pupil region that incides collector lens fully, and can improve the utilization ratio of laser.In addition, even laser processing device 2 and the laser processing of the 2nd embodiment by intensity-conversion lens 11, also can not destroy the surface of workpiece, and can only process expeditiously inside.

[the 3rd embodiment]

Figure 20 means the pie graph of the laser processing device that the 3rd embodiment of the present invention is related.The laser processing device 3 of the 3rd embodiment is in laser processing device 2, and is different from the 2nd embodiment on the formation that further possesses speculum 21,22 and imaging optical system 40.Other formation of laser processing device 3 is identical with laser processing device 2.

Speculum 21,22 makes the direct of travel of the laser that comes from phase place correction lens 12 change 90 °.Particularly, speculum 21,22 makes respectively the direct of travel of laser change one by one 135 °, its result, and the direct of travel that comes from the laser of phase place correction lens 12 changes 90 °, and towards imaging optical system 40.

Imaging optical system 40 has a pair of lens 41,42, and with the laser imaging on the light incident side imaging surface in the exiting side imaging surface.The light incident side imaging surface of imaging optical system 40 is set in the exit facet of phase place correction lens 12, and the exiting side imaging surface is set in the pupil face of collector lens 50.Also have, the preferred beam diameter as making the laser on the light incident side imaging surface of imaging optical system 40 be suitable for collector lens 50 the pupil face size the expansion optical system or dwindle optical system and bring into play function.Thus, can utilize the laser of the pupil region that incides collector lens 50 fully, it is relatively better that the utilization ratio of laser becomes.

Even the laser processing device 3 of the 3rd embodiment also can obtain the advantage identical with the laser processing device 2 of the 2nd embodiment.

Have again, laser processing device 3 according to the 3rd embodiment, because can be made wave surface after phase place correction lens 12 are propagated image in the pupil face of collector lens 50 by imaging optical system 40, so in the situation that phase place correction lens 12 can not to be disposed at such near the pupil face of laser lens 50 be suitable.

[the 4th embodiment]

Figure 21 means the pie graph of the laser processing device that the 4th embodiment of the present invention is related.The laser processing device 4 of the 4th embodiment possesses beam splitter (beam splitter) 91 and further possesses beam splitter 92 and observe with different from the 3rd embodiment on the formation of optical system 90 in laser processing device 3 replacing speculum 22.Other formation of laser processing device 4 is identical with laser processing device 3.

Observation has camera 95, lens 96 and light source 97 with optical system 90.Light source 97 light shines workpiece 100 by beam splitter 91,92, imaging optical system 40, dichronic mirror 61,71 and collector lens 50.Then, camera 95 is to observe the camera of workpiece 100 for scioptics 96, beam splitter 92,91, imaging optical system 40, dichronic mirror 61,71 and collector lens 50.

Even the laser processing device 4 of the 4th embodiment also can be obtained the advantage identical with the laser processing device 3 of the 3rd embodiment.

In addition, according to the laser processing device 4 of the 4th embodiment, can observe workpiece 100 in Laser Processing.

[the 5th embodiment]

Figure 22 means the pie graph of the laser processing device that the 5th embodiment of the present invention is related.The laser processing device 5 of the 5th embodiment possesses on the mode of attenuator 30A, speculum 23,24,25,26,27 different from the 3rd embodiment in laser processing device 3 replacing amplifier 30 and speculum 21,22.

More specifically, speculum 23 ~ 27th makes respectively the direct of travel of laser change one by one the speculum of 90 °, its result, and the direct of travel that comes from the laser of LASER Light Source 20 changes 90 °.Dispose attenuator 30A between speculum 23 and speculum 24, dispose intensity-conversion lens 11 between speculum 24 and speculum 25, dispose a plurality of phase place correction lens 12 and lens mount 15 between speculum 25 and speculum 26, lens 41 dispose imaging optical system 40 between speculum 26 and speculum 27 in, another lens 42 dispose imaging optical system 40 between speculum 27 and dichronic mirror 61 in.

Attenuator 30A has λ/2 wavelength plate 31A, polarization beam splitter 32A, shock absorber 33A, and the Laser output that will have the polarization plane of regulation arrives intensity-conversion lens 11.Other formation of laser processing device 5 is identical with laser processing device 3.

Even the laser processing device 5 of the 5th embodiment also can be obtained the advantage identical with the laser processing device 3 of the 3rd embodiment.

Also have, the present invention is not limited to above-described present embodiment, and various distortion are fine.For example, in the present embodiment, illustration switch the mode of a plurality of intensity-conversion lens 11 or a plurality of phase place correction lens 12 by the lens mount 15 of rotational circle plate-like, but the method for switching a plurality of intensity-conversion lens 11 or a plurality of phase place correction lens 12 is not limited thereto.For example, laser processing device 1A ~ 3A as illustrated in Figure 23 ~ 25, in the laser processing device 1 ~ 3 of the 1st ~ the 3rd embodiment, also can replace discoid lens mount 15 and possess banded lens mount 15A.In the case, be arranged in banded lens mount 15A by a plurality of intensity-conversion lens 11 or a plurality of phase place correction lens 12, lens mount 15A slides, thereby optionally switches a plurality of intensity-conversion lens 11 or a plurality of phase place correction lens 12.

In addition, in the present embodiment, illustration only switch the mode of the side in a plurality of intensity-conversion lens 11 and a plurality of phase place correction lens 12, but the both sides that also can switch a plurality of intensity-conversion lens 11 and a plurality of phase place correction lens 12.Accordingly, by the combination of the correction wave surface of the correction wave surface of a plurality of intensity-conversion lens 11 and a plurality of phase place correction lens 12, can carry out more accurate aberration correction.

Claims (4)

1. laser processing device is characterized in that:

With the laser processing device of laser focusing in the workpiece inside with photopermeability,

Possess:

Light source generates laser;

The polishing shaped part is changed the intensity distribution of the laser that comes from described light source and is shaped as desirable intensity distribution;

Collector lens, the Working position of the laser focusing that will come from described polishing shaped part in described workpiece inside; And

Control part is controlled described polishing shaped part,

Described polishing shaped part has:

A plurality of intensity-conversion lens are changed the intensity distribution of the laser that comes from described light source and are shaped as desirable intensity distribution, and generating respectively different wave surfaces, perhaps

Described polishing shaped part has:

Conversion come from described light source laser intensity distribution and be shaped as the phase place of the intensity-conversion lens of desirable intensity distribution and the shoot laser that correction comes from these intensity-conversion lens and generate respectively a plurality of phase place correction lens of different wave surfaces,

Described control part is in the situation that the described Working position of change switches described a plurality of intensity-conversion lens or described a plurality of phase place correction lens.

2. laser processing device as claimed in claim 1 is characterized in that:

Described a plurality of intensity-conversion lens or described a plurality of phase place correction lens generate respectively for the aberration of revising laser and correspond respectively to different of a plurality of correction wave surfaces of a plurality of Working positions of described workpiece inside,

Described control part is in the situation that the described a plurality of Working positions of change, select to generate corresponding to the lens of the correction wave surface of the Working position of this change from described a plurality of intensity-conversion lens or described a plurality of phase place correction lens and switches.

3. laser processing is characterized in that:

The laser processing of laser processing device,

Described laser processing device possesses:

Generate the light source of laser;

Conversion come from described light source laser intensity distribution and be shaped as the polishing shaped part of desirable intensity distribution;

The collector lens of the Working position of the laser focusing that will come from described polishing shaped part in described workpiece inside,

Described polishing shaped part has:

A plurality of intensity-conversion lens are changed the intensity distribution of the laser that comes from described light source and are shaped as desirable intensity distribution, and generating respectively different wave surfaces, perhaps

Described polishing shaped part has:

Conversion come from described light source laser intensity distribution and be shaped as the phase place of the intensity-conversion lens of desirable intensity distribution and the shoot laser that correction comes from these intensity-conversion lens and generate respectively a plurality of phase place correction lens of different wave surfaces,

Set or change the Working position in described workpiece inside,

Corresponding to setting or the change of described Working position, switch described a plurality of intensity-conversion lens or described a plurality of phase place correction lens,

The Working position of Ear Mucosa Treated by He Ne Laser Irradiation in described workpiece that will come from described light source.

4. laser processing as claimed in claim 3 is characterized in that:

Described a plurality of intensity-conversion lens or described a plurality of phase place correction lens generate respectively for the aberration of revising laser and correspond respectively to different of a plurality of correction wave surfaces of a plurality of Working positions of described workpiece inside,

Corresponding to setting or the change of described a plurality of Working positions, select generation corresponding to the lens of the correction wave surface of the Working position of this setting or change from described a plurality of intensity-conversion lens or described a plurality of phase place correction lens and switch.

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